Bracket angle adjustment mechanism

ABSTRACT

A bracket angle adjustment mechanism has two wedge members ( 16 A,  16 B) fit in an eccentric space between a large-diameter hole ( 14   c ) of an external-tooth gear ( 14 ) and a small-diameter shank ( 15   c ) of an internal-tooth gear ( 15 ), and a wedged-state release member ( 19 ) is held by the external-tooth gear ( 14 ) so that an outer peripheral surface of the wedged-state release member ( 19 ) is fit rotatably into the large-diameter hole ( 14   c ). The wedged-state release member ( 19 ) has a clearance groove ( 19   a ) for avoiding interference with the wedge members ( 16 A,  16 B), a wedged-state release portion ( 19   e ), and a noncircular mounting hole ( 19   d ) non-rotatably fit with a attaching portion of a control shaft ( 20 ) penetrating through the small-diameter shank ( 15   c ) in a non-fitting manner. The bracket angle adjustment mechanism achieves enhanced strength and lower production cost, based on the improved mounting position of the wedged-state release member.

BACKGROUND OF THE INVENTION

1. Field of the Invention

The present invention relates to a bracket angle adjustment mechanism.

2. Description of the Related Art

Heretofore, there has been known one type of bracket angle adjustment mechanism. For example, in a vehicle seat assembly 1 as shown in FIG. 21, the bracket angle adjustment mechanism comprises a first bracket 4 fixed to a seat cushion 2, and a second bracket 5 fixed to a seat back 3, wherein a handle 7 fixed to a control shaft 6 is manually rotated clockwise or counterclockwise to adjust an angle of the second bracket 5 relative to the first bracket 4, i.e. a frontward/rearward reclining angle of the seat back 3 (see, for example, Japanese Patent Publication No. 63-47443: Patent Publication 1).

More specifically, the first bracket 4 includes an external-tooth gear 4 a, and the second bracket 5 includes an internal-tooth gear 5 a which has a larger number of teeth than that of the external-tooth gear 4 a. The control shaft 6 has an inward end supported by a central hole 5 b of the second bracket 5.

The bracket angle adjustment mechanism further includes a pair of wedge members 11A, 11B and a spring member 12. The pair of wedge members 11A, 11B are fitted in an eccentric space 10 which is defined between an inner peripheral surface of a large-diameter hole 4 a formed in a central region of the external-tooth gear 4 a and an outer peripheral surface of a small-diameter shank 9 a integral with or constituting a central portion of the internal-tooth gear 5 a (in this conventional example, the small-diameter shank 9 a corresponds to a given circumferential portion 9 a of a follower disk 9 fixed to the control shaft 6), when respective portions of the external-tooth gear 4 a and the internal-tooth gear 5 a are engaged with one another. The spring member 12 is interposed between the pair of wedge members 11A, 11B in the eccentric space to apply a biasing force to each of the wedge members 11A, 11B in a wedging direction, i.e. in a direction allowing each of the wedge members 11A, 11B to be wedged between the inner peripheral surface of the large-diameter central hole 4 a and the outer peripheral surface of the small-diameter central shank 9 a. The control shaft 6 is adapted to move a wedged-state releasing portion (which corresponds to a follower protrusion 9 b formed in the follower disk 9) located between respective wedging ends of the wedge members 11A, 11B. In FIG. 21C, the reference numeral 13 indicates a cover plate fixed to the second bracket 5. The cover plate 13 extends to cover the external-tooth gear 4 a of the first bracket 4, and has a bearing portion 13 a supporting an outward portion of the control shaft 13 a.

In an operation for adjusting an angle of the second bracket 5 relative to the first bracket 4, i.e. a frontward/rearward reclining angle of the seat back 3, the handle 7 is manually rotated to rotate the control shaft 6. In conjunction with the rotation of the control shaft 6, the wedged-state releasing portion 9 b is rotated to move the pair of wedge members 11A, 11B together with the spring member 12 circularly in the eccentric space 10, so that the small-diameter shank 9 a is eccentrically moved relative to the large-diameter hole 4 b to allow an engagement position of the internal-tooth gear 5 a relative to the external-tooth gear 4 a to be changed.

As shown in FIG. 22, there has also been known a bracket angle adjustment mechanism which comprises a pair of wedge members fitted into an eccentric space 10 defined between a large-diameter hole 4 a formed in a central region of a first bracket 4 and a small-diameter shank 5 c constituting a central portion of a second bracket 5, a wedged-state release member 8 having a wedged-state release portion 8 a and a tubular portion 8 b fitted in a small-diameter shank 5 c of a second bracket 5, and a control shaft 6 fitted into and splined to the tubular portion 8 b (see Japanese Patent Publication No. 07-284422: Patent Publication 2).

In the bracket angle adjustment mechanisms as disclosed in the Patent Publications 1 and 2, there remain much needs to be improved. For example, in the bracket angle adjustment mechanisms as disclosed in the Patent Publication 2, the tubular portion 8 b of the wedged-state release member 8 is fitted in the small-diameter shank 5 c of the second bracket 5, and the control shaft 6 is fitted into and splined to the tubular portion 8 b. Thus, in connection with layout conditions, this mechanism has difficulties in increasing a thickness of the small-diameter shank 5 c of the second bracket 5 and the tubular portion 8 b of the wedged-state release member 8, and in including a diameter of the control shaft 6.

Moreover, this mechanism has a problem about increase in production cost due to the need for the spline connection between the control shaft 6 and the tubular portion 8 b of the wedged-state release member 8, and a complicated shape of the wedged-state release mechanical 8.

SUMMARY OF THE INVENTION

In view of the above problem, it is an object of the present invention to provide a bracket angle adjustment mechanism which can achieve enhanced strength and lower production cost, based on improvement in a mounting position of a wedged-state release member.

According to an aspect of the invention, a bracket angle adjustment mechanism is provided with: a first bracket including an external-tooth gear; a second bracket including an internal-tooth gear which has a larger number of internal teeth than that of external teeth of the external-tooth gear; a pair of wedge members fitted in an eccentric space which is defined between a large-diameter hole formed in a central region of the external-tooth gear and a small-diameter shank constituting a central portion of the internal-tooth gear, in a state when the external-tooth gear and the internal-tooth gear are partly engaged with one another; a spring member applying a biasing force to each of the pair of wedge members in a wedging direction; and a wedged-state release member disposed between respective wedging-directional leading edges of the pair of wedge members. The wedged-state release member is operable, when rotated by a control shaft associated therewith, to move the pair of wedge members together with the spring member in a wedged-state release direction circularly in the eccentric space, whereby the small-diameter shank is eccentrically moved relative to the large-diameter hole to allow an engagement position of the internal-tooth gear relative to the external-tooth gear to be changed so as to adjust an angle of the second bracket relative to the first bracket. The wedged-state release member is held by the external-tooth gear in such a manner that an outer peripheral surface of the wedged-state release member is rotatably fitted into the large-diameter hole formed in the central region of the external-tooth gear.

These and other objects, features, aspects, and advantages of the present invention will become more apparent from the following detailed description of the preferred embodiments/examples with reference to the accompanying drawings.

BRIEF DESCRIPTION OF DRAWINGS

FIG. 1 is an exploded perspective view showing a bracket angle adjustment mechanism according to one embodiment of the present invention, wherein the mechanism is applied to a vehicle seat assembly.

FIG. 2 is an exploded perspective view showing the bracket angle adjustment mechanism in FIG. 1, when viewed from the side of an outer surface of a second bracket thereof.

FIG. 3 is an exploded perspective view showing the bracket angle adjustment mechanism in FIG. 1, when viewed from the side of an outer surface of a first bracket thereof.

FIG. 4 illustrates a gear unit of the bracket angle adjustment mechanism in FIG. 1, wherein FIG. 4A is a perspective view showing the gear unit together with the first bracket, and FIG. 4B is an enlarged perspective view showing the gear unit.

FIG. 5 illustrates the gear unit in FIG. 4, wherein FIG. 5A is a top plan view, and FIG. 5B is a front plan view.

FIG. 6 illustrates the gear unit in FIG. 5, wherein FIG. 6A is a sectional view taken along the line A-A in FIG. 5B, and FIG. 6B is a sectional view taken along the line B-B in FIG. 5B.

FIG. 7 is a sectional view taken along the line C-C in FIG. 8.

FIG. 8 is a vertical sectional view showing the bracket angle adjustment mechanism in FIG. 1.

FIG. 9 illustrates a wedged-state release member of the bracket angle adjustment mechanism in FIG. 1, wherein FIG. 9A is a front view, and FIG. 9B is a side view.

FIG. 10 illustrates a part of teeth in the bracket angle adjustment mechanism in FIG. 1, wherein FIG. 10A is an enlarged view showing internal teeth, and FIG. 10B is an enlarged view showing external teeth.

FIG. 11 illustrates a state of tooth engagement, wherein FIG. 11A is an enlarged view showing an engagement state of the internal and external teeth in the bracket angle adjustment mechanism in FIG. 1, and FIG. 11B is an enlarged view showing an engagement state of internal and external teeth in a conventional bracket angle adjustment mechanism.

FIG. 12 illustrates internal-tooth and external-tooth gears in the bracket angle adjustment mechanism in FIG. 1, wherein FIG. 12A is a front view showing an engagement state thereof, and FIG. 12B is a schematic diagram showing respective reference circles of the internal teeth and external teeth thereof.

FIG. 13 is a front view showing a wedge member of the bracket angle adjustment mechanism in FIG. 1, in the state when no load acts on a seat back of the vehicle seat assembly.

FIG. 14 is a front view showing the wedge member, in the state when a load acts on the seat back.

FIG. 15 illustrates one modification of a wedge member, wherein FIG. 15A is a front view showing the wedge member in a normal position, and FIG. 15B is a front-view showing the wedge member in a wedged position.

FIG. 16 illustrates the wedge member in FIG. 15 and a wedged-state release member, wherein FIG. 16A is a front views showing them in a normal position, and FIG. 16B is a front views showing them in a non-wedged position.

FIG. 17 is an explanatory diagram showing an operation of the wedge member and the wedged-state release member in FIGS. 15 and 16.

FIG. 18 is an explanatory diagram showing an operation of another modification of a wedge member and a wedged-state release member.

FIG. 19 is an explanatory diagram showing an operation of yet another modification of a wedge member and a wedged-state release member.

FIG. 20 is a perspective view showing still another modification of a wedge member and a wedged-state release member.

FIG. 21 illustrates a conventional bracket angle adjustment mechanism, wherein FIG. 21A is a perspective view showing a vehicle sheet assembly equipped therewith, and FIGS. 21B and 21C are, respectively, a partially sectional front view and a sectional side view showing the conventional bracket angle adjustment mechanism.

FIG. 22 illustrates another conventional bracket angle adjustment mechanism, wherein FIG. 22A is a sectional view thereof, and FIG. 22B is a partially sectional front view thereof

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS

With reference to the drawings, a best mode for carrying out the present invention will now be described. In the related figures, structurally/functionally the same element or component as that of the conventional example in FIG. 21 is defined by the same reference numeral, and its detailed description will be omitted.

A bracket angle adjustment mechanism according to one embodiment of the present invention is incorporated in a vehicle seat assembly 1 having a seat cushion 2 and a seat back 3. As shown in FIGS. 1 to 3 and FIG. 8, the bracket angle adjustment mechanism comprises a first bracket 4 which is fixed to the seat cushion 2 using a bolt (not shown) penetrating through each of two bolt holes 4 d formed in the first bracket 4, and a second bracket 5 which is fixed to the seat back 3 using a bolt (not shown) penetrating through each of two bolt holes 4 d formed in the second bracket 5. The bracket angle adjustment mechanism is designed to adjust an angle of the second bracket 5 relative to the first bracket 4, i.e. a frontward/rearward inclining angle of the seat back 3 relative to the seat cushion 2, according to rotation of a control shaft 20 in conjunction with a clockwise/counterclockwise rotation of a handle 7 fixed thereto. In this embodiment, the first and second brackets 4, 5 and after-mentioned associated components, such as a gear unit U, are fixed to either one of opposite lateral sides of the seat assembly 1.

The bracket angle adjustment mechanism includes an external-tooth gear 14 and an internal-tooth gear 15. The external-tooth gear 14 is integrally formed in a first disk-shaped plate member by partly pressing an outer surface of the first plate member inward in such a manner as to allow an inner surface thereof to have a convex portion with a plurality of external teeth. The internal-tooth gear 15 is integrally formed in a second disk-shaped plate member by partly pressing an inner surface of the second plate member outward in such a manner as to allow an outer surface thereof to have a concave portion with a plurality of internal teeth. The external-tooth gear 14 and the internal-tooth gear 15 are assembled together as an after-mentioned gear unit U. Then, the external-tooth gear 14 is fixed to the first bracket 4, for example, by welding after a plurality (eight in this embodiment) of protrusions formed in the outside surface of the external-tooth gear 14 is fitted into a plurality of corresponding positioning holes formed in the first bracket 4. Further, the internal-tooth gear 15 is fixed to the second bracket 5, for example, by welding after a plurality (eight in this embodiment) of protrusions formed in the outside surface of the internal-tooth gear 15 is fitted into a plurality of corresponding positioning holes formed in the second bracket 5. Alternatively, as with the conventional bracket angle adjustment mechanism, the external-tooth gear 14 may be integrally formed in the first bracket 4 by partly pressing an outer surface of the first bracket 4 inward in such a manner as to allow an inner surface thereof to have a convex portion with a plurality of external teeth, and the internal-tooth gear 15 may integrally formed in the second bracket 5 by partly pressing an inner surface of the second bracket 5 outward in such a manner as to allow an outer surface thereof to have a concave portion with a plurality of internal teeth.

The internal teeth 15 b of the internal-tooth gear 15 are formed in a number (fifty in this embodiment) greater than that (forty nine in this embodiment) of the external teeth 14 b of the external-tooth gear 14. Each shape of the external teeth 14 b of the external-tooth gear 14 and the internal teeth 15 b of the internal-tooth gear 15 will be described in detail later with reference to FIGS. 10 and 11.

The external-tooth gear 14 has a central region formed as a large-diameter hole 14 c, and the internal-tooth gear 15 has a central region formed as a hollow small-diameter shank 15 c protruding into the large-diameter hole 14 c of the external-tooth gear 14. The first bracket 4 is formed with a hole 4 e corresponding to the large-diameter hole 14 c of the external-tooth gear 14, and the second bracket 5 is formed with a hole 5 e corresponding to the small-diameter shank 15 c of the internal-tooth gear 15.

The bracket angle adjustment mechanism includes a ring-shaped retainer member 22 fitted on an outer peripheral surface of the first plate member having the external-tooth gear 14. The ring-shaped retainer member 22 has an outer peripheral portion formed as a plurality (twelve in this embodiment) of pawls 22 a. In the assembling process of the gear unit U, these pawls 22 a are engaged with a plurality of corresponding cutout portions formed in an outer peripheral surface of the second plate member having the internal-tooth gear 15, and then folded downward in a crimping manner, so that the external-tooth gear 14 and the internal-tooth gear 15 are assembled together as the gear unit U where the external teeth 14 b of the external-tooth gear 14 and the internal teeth 15 b of the internal-tooth gear 15 are partly engaged with each other while allowing a relative movement between the external-tooth gear 14 and the internal-tooth gear 15, as shown in FIGS. 5 and 6. While the ring-shaped retainer member 22 in this embodiment is designed to crimpingly hold the external-tooth gear 14 from the side of the internal-tooth gear 15, it may be designed to crimpingly hold the internal-tooth gear 15 from the side of the external-tooth gear 14. Further, in place of the ring-shaped retainer member 22, the external-tooth gear 14 and the internal-tooth gear 15 may be fastened together using a presser member fixed to either one of the first and second brackets 4, 5 by welding or riveting.

The bracket angle adjustment mechanism further includes a pair of wedge members 16A, 16B, a spring member 18 and a wedged-state release member 19. As shown in FIG. 4, after the external-tooth gear 14 and the internal-tooth gear 15 are assembled together as the gear unit U using the ring-shaped retainer member 22, these components are incorporated into an after-mentioned eccentric space 10 etc., from a large-diameter opening 22 b of the ring-shaped retainer member 22. Specifically, the spring member 18 has an outer shape or outer dimensions allowing for being housed in an inner space of the wedged-state release member 19. As shown in FIG. 8, when the external-tooth gear 14 is fixed to the first bracket 4, for example, by welding after fitting the protrusions 14 a of the external-tooth gear 14 into the positioning holes 4 c of the first bracket 4, the wedged-state release member 19 is pressed by a concave portion 4 a surrounding the hole 4 e of the first bracket 4, and thereby kept from dropping out of the large-diameter hole 14 c.

As specifically shown in FIGS. 7 and 8, when the external teeth 14 b of the external-tooth gear 14 and the internal teeth 15 b of the internal-tooth gear 15 are partly engaged with each other, an eccentric space 10 is defined between an inner peripheral surface of the large-diameter hole 14 c of the external-tooth gear 14 and an outer peripheral surface of the small-diameter shank 15 c of the internal-tooth gear 15. The pair of wedge members 16A, 16B is fitted into this eccentric space 10.

The large-diameter hole 14 c of the external-tooth gear 14 is formed to have a hole length equal to a thickness of the first plate member, and each of the wedge members 16A, 16B is also formed to have a thickness equal to the thickness of the first plate member.

In one of conventional bracket angle adjustment mechanisms, a ring-shaped member having a length greater than the thickness of the first plate member is additionally fitted in the inner surface of the large-diameter hole 14 c so as to allow the large-diameter hole 14 c of the external-tooth gear 14 to have a hole length greater than the thickness of the first plate member, and each of the wedge members 16A, 16B is formed to have a thickness greater than the thickness of the first plate member. While this technique is intended to increase the thickness of each of the wedge members 16A, 16B so as to provide an increased contact surface with the inner peripheral surface of the large-diameter hole 14 c and the outer peripheral surface of the small-diameter shank 15 c, the ring-shaped member will undesirably protrude beyond the thickness of the first plate member to cause increase in the entire thickness of the bracket angle adjustment mechanism.

In contrast, the above structure in this embodiment, where the large-diameter hole 14 c of the external-tooth gear 14 is formed to have a hole length equal to a thickness of the first plate member, and each of the wedge members 16A, 16B is also formed to have a thickness equal to the thickness of the first plate member, makes it possible to omit the ring-shaped member protruding beyond the thickness of the first plate member, so as to reduce the entire thickness of the bracket angle adjustment mechanism. Further, as measures for increasing a contact surface of each of the wedge members 16A, 16B relative to the inner peripheral surface of the large-diameter hole 14 c and the outer peripheral surface of the small-diameter shank 15 c, each of the wedge members 16A, 16B may be formed to increase each circumferential length of an arc-shaped outer surface 16 a and an arc-shaped inner surface 16 a, as described in detail with reference to FIG. 15.

Each of the wedge members 16A, 16B is formed to have an arc-shaped outer surface 16 a approximately along the arc-shaped inner peripheral surface of the large-diameter hole 14 c of the external-tooth gear 14, and an arc-shaped inner surface 16 b approximately along the arc-shaped outer peripheral surface of the small-diameter shank 15 c of the internal-tooth gear 15. Each of the wedge members 16A, 16B is also formed in a wedge shape which is gradually increased in width in a direction from a leading edge to a trailing edge thereof. The respective shapes of the arc-shaped outer surface 16 a and the arc-shaped inner surface 16 b of each of the wedge members 16A, 16B will be described in detail later with reference to FIGS. 13 and 14.

The spring member 18 is formed in an approximately Ω shape having outer dimensions less than that of the inner peripheral surface 14 c of the external-tooth gear 14. As shown in FIG. 7, the spring member 18 has one end 18 a engaged with a concave portion 16 e formed in the trailing edge 16 d of one 16A of the wedge members, and the other end 18 b engaged with a concave portion 16 e formed in the trailing edge 16 d of the other wedge member 16B. Thus, the spring member 18 is operable to apply a biasing force to each of the wedge members 16A, 16B in a wedging direction f allowing each of the wedge members 16A, 16B to be wedged between the inner peripheral surface of the large-diameter hole 14 c of the external-tooth gear 14 and the outer peripheral surface of the small-diameter shank 15 c of the internal-tooth gear 15 in the eccentric space 10.

The wedged-state release member 19 is formed in a bottomed cylindrical shape, and rotatably fitted in the inner peripheral surface of the large-diameter hole 14 c of the external-tooth gear 14. As specifically shown in FIG. 9, the wedged-state release member 19 is formed with a plurality of clearance grooves 19 a, a pair of pressing portions 19 b, and a noncircular hole 19 d in a bottom 19 c thereof. In the state after the wedged-state release member 19 is fitted in the large-diameter hole 14 c, the clearance grooves 19 a serve as a means to avoid excessive interference between the wedged-state release member 19 and the wedge members 16A, 16B, and each of the pressing portions 19 b serves as a means to press a corresponding one of the wedge members 16A, 16B so as to prevent it from rising toward the wedged-state release member 19. Further, the noncircular hole 19 d is engaged with a non circular portion 20 a of an after-mentioned control shaft 20 in a non-rotatable manner relative to the wedged-state release member 19.

The wedged-state release member 19 is further formed with an half-round arc-shaped wedged-state release portion 19 e is located between the respective wedging or leading edges 19 c of the wedge members 16A, 16B. For example, in FIG. 7, when the wedged-state release member 19 is rotated clockwise, one 19 a of opposite edges of the wedged-state release portion 19 e is brought into contact with the leading edge 16 c of the wedge member 16A. When the wedged-state release member 19 is rotated counterclockwise, the other edge 19 g of the wedged-state release portion 19 e is brought into contact with the leading edge 16 c of the wedge member 16B. The wedged-state release member 19 is rotatably fitted in the inner peripheral surface 14 c of the external-tooth gear 14 through the wedged-state release portion 19 e and an arc-shaped portion 19 h formed in the wedged-state release member 19 at a position opposed to the wedged-state release portion 19 e.

With Reference to FIG. 8, after inserted from the hole 5 e of the second bracket 5 fixed to either one of opposite lateral sides of the seat assembly 1, the noncircular portion of the control shaft 20 is inserted through a hole 15 e of the small-diameter shank 15 c of the internal-tooth gear 15 with a sufficient clearance therebetween, and then engaged with the noncircular portion 19 d of the wedged-state release member 19 in a non-rotatable manner relative thereto.

The noncircular portion 20 a is formed at each of opposite ends of the control shaft 20 to allow the control shaft 20 to be rotated in conjunction with the handle 7 and the gear unit U. In this embodiment, the noncircular portion 20 a has an oval shape formed by pressingly deforming a pipe-like material of the control shaft 20 from both sides thereof. The noncircular hole 19 d of the wedged-state release member 19 is formed in an oval shape conformable to the oval shape of the noncircular portion 20 a.

While each of the noncircular portion 19 d of the wedged-state release member 19 and the noncircular portion 20 a of the control shaft 20 in this embodiment is formed in an oval shape, it may have any other suitable noncircular shape, such as a polygonal shape. Further, the control shaft 20 may be entirely formed as the noncircular portion 20 a through an extrusion process or a drawing process. Instead of engaging the noncircular portion 19 d of the wedged-state release member 19 with the noncircular portion 20 a of the control shaft 20 in a non-rotatable manner relative thereto, a circular-shaped portion of the wedged-state release member 19 may be fitted into a circular-shaped hole of the control shaft 20, and then crimpingly joined together in a non-rotatable manner relative to one another. Alternatively, the wedged-state release member 19 and the control shaft 20 may be designed, respectively, to have a noncircular-shaped shank fixed thereto or formed therein and a corresponding noncircular-shaped hole formed therein. In this case, the noncircular-shaped shank may be engaged with the noncircular-shaped hole in a non-rotatable manner relative to one another. The wedged-state release member 19 can be prepared by subjecting a metal plate to a press forming process, or through a zinc die-casting process, or a plastic molding process.

In an operation for fixedly attaching the handle 7 to be manually rotated, to one end of the control shaft 20, a corresponding one of the noncircular portions 20 a is protruded outward, and inserted into a shaft-receiving portion 7 a (see FIG. 1) formed in the handle 7 in a non-rotatable manner. Alternatively, in a type having no control shaft 20, the wedged-state release member 19 may be designed to be rotated directly by the handle 7. The mechanism designed to manually rotate the wedged-state release member 19 directly by the handle 7 can provide further enhanced operational feeling.

When the control shaft 20 (or the wedged-state release member 19) is rotated by an electric motor in place of the handle 7, a device (such as a gear, belt or chain pulley) interlocking with the electric motor may be attached to an appropriate position of the control shaft 20.

For example, in FIG. 7, when the wedged-state release member 19 is rotated clockwise according to rotation of the control shaft 20 in conjunction with a manual operation of the handle 7, one edge 19 f of the wedged-state release portion 19 e is brought into contact with the leading edge 16 c of the wedge member 16A, to move the wedge member 16A clockwise so as to loosen the wedged state of the wedge member 16A. In conjunction with the clockwise movement of the wedge member 16A, the wedge member 16B is also moved clockwise through the spring member 18.

Thus, the pair of wedge members 16A, 16B are moved together with the spring 10 circularly in the eccentric space 10, so that the small-diameter shank 15 c of the internal-tooth gear 15 is eccentrically moved relative to the large-diameter hole 4 b of the external-tooth gear 14 to allow an engagement position of the internal teeth 15 a relative to the external teeth 14 b to be changed (when the handle 7 is manually rotated 360 degrees, a wedge members 16A, 16B are moved one round, and an internal-teeth gear 15 is rotated by an angle equivalent to one of the external teeth of the external-tooth gear 14). Thus, an angle of the second bracket 5 relative to the first bracket 4, i.e. a frontward/rearward reclining angle of the seat back 3, can be adjusted.

As specifically shown in FIG. 10, each of the external teeth 14 b of the external-tooth gear 14 is designed such that a half-round shape drawn using a radius “ra” having a single center defined by a point “a” on the reference circle PC (14) is formed in a region of-an addendum TI or in a range between a reference circle PC (14) and an addendum or tip circle AC (14), and an undercut shape is formed in a region of a dedendum T2 or in a range between the reference circle PC (14) and a dedendum or root circle DC (14).

The reference circle PC (14) has an arc shape. Thus, in the strict sense, the region of the addendum T1 in each of the external teeth 14 b has an approximately half-round shape until the above half-round shape drawn by the radius “ra” comes into contact with the arc of the reference circle PC (14).

Preferably, the undercut shape in the region of the dedendum T2 is formed as an arc shape which is drawn by a radius “rb” in such a manner as to be continuously connected to the root circle DC (14). This undercut shape makes it possible to eliminate the risk of formation of a step at a joint between the respective regions of the addendum T1 and the dedendum T2, so as to provide enhanced strength in the external teeth 14 b.

Each of the internal teeth 15 b of the internal-tooth gear 15 is designed to be formed as an arc shape free of interference with the region of the half-round addendum T1 in a corresponding one of the external teeth 14 b of the external-tooth gear 14. Preferably, the arc shape of the internal tooth 15 b in the internal-tooth gear 15 is formed as a combination of two quarter-round shapes drawn, respectively, using radii “rb”, “rc” having two centers defined by points “b”, “c” on the reference circle PC (15).

As above, each of the external teeth 14 b of the external-tooth gear 14 is designed such that a half-round shape having a single center defined by a point “a” on the reference circle PC (14) is formed in the region of the addendum T1 or in the range between the reference circle PC (14) and the tip circle AC (14), and an undercut shape is formed in the region of the dedendum T2 or in the range between the reference circle PC (14) and the root circle DC (14). Further, each of the internal teeth 15 b of the internal-tooth gear 15 is designed to be formed as an arc shape free of interference with the region of the half-round addendum T1.

According to the above shapes, as shown in FIG. 11A, when the external-tooth gear 14 is rotated counterclockwise R, a load F of the external tooth 14 b having a half-round-shaped region in the addendum T1 constantly acts on the arc-shaped internal tooth 15 b at a right angle in a rotation direction. Thus, as compared with a pressure angle θ between the external and internal teeth 4 a, 5 a with a conventional involute tooth profile as shown in FIG. 11B, a pressure angle θ between the external and internal teeth 14 b, 15 b becomes smaller. This provides enhanced transmission efficiency to allow an operating force for rotating the control shaft 20 to be reduced. In addition, as compared with the conventional pressure angle θ′, the pressure angle θ is located on the inward side relative to a tangent line L. This makes it possible to reduce a load acting on the control shaft 20. Furthermore, as shown in FIGS. 12A and 12B, a range W having an interest between the reference circle PC (14) of the external teeth 14 b and the reference circle PC (15) of the internal teeth 15 b is created. Thus, the engagement between the external teeth 14 b and the internal teeth 15 b becomes deeper in this region.

According to the above bracket angle adjustment mechanism, in an operation for rotating the control shaft 20 using the handle 7, the handle 7 can be manually rotated by a smaller operating force. Otherwise, when the control shaft 20 is rotated using an electric pump, the control shaft 20 can be rotated by a lower output power of the electric motor. This makes it possible to use a smaller/lighter electric motor.

In addition, the above advantages can be obtained only by changing the shapes of the external teeth 14 b of the external-tooth gear 14 and the internal teeth 15 b of the internal-tooth gear 15. Thus, the bracket angle adjustment mechanism can be produced in a significantly simplified structure at a low cost.

As specifically shown in FIG. 13, each of the pair of wedge members 16A, 16B in the above embodiment has an arc-shaped outer surface 16 a having a diameter slightly less than that of the arc-shaped inner peripheral surface of the large-diameter hole 14 c of the external-tooth gear 14, and an arc-shaped inner surface 16 b having a diameter slightly greater than that of the arc-shaped outer peripheral surface of the small-diameter shank 15 c of the internal-tooth gear 15.

FIG. 13 shows a state when no load acts on the seat back 3 (second bracket 5). The bracket angle adjustment mechanism according to this embodiment is designed such that, in this state, a line K connecting between an internal-tooth receiving point “a” where the arc-shaped inner surface 16 b of the wedge member 16B comes into contact with the arc-shaped outer peripheral surface of the small-diameter shank 15 c of the internal-tooth gear 15, and an external-tooth receiving point “b” where the arc-shaped outer surface 16 a of the wedge member 16B comes into contact with the arc-shaped inner peripheral surface of the large-diameter hole 14 c of the external-tooth gear 14, is located outward or offset relative to each of a gear center P2 of the external-tooth gear 14 and a gear center P1 of the internal-tooth gear 15. The line K is spaced apart from the gear center P1 by a distance “j”, and an intersecting point “q” between the line K and a line I extending from the gear center P1, in the distance “j”, corresponds to a force application point or action point of the internal-tooth receiving point “a” and the external-tooth receiving point “b” of the wedge member 16B. In FIG. 13, P3 indicates a center of the arc-shaped outer surface 16 a of the wedge member 16B, and P4 indicates a center of the arc-shaped inner surface 16 b of the wedge member 16B. Although not shown herein, the wedge member 16A has the same effects as those of the wedge member 16B as well as the following effects.

As shown in FIG. 14, when a load F is imposed on the second bracket 5 from the seat back 3 clockwise, the load F acts on the small-diameter shank 15 c of the internal-tooth gear 15, on the basis of an engagement point between the internal teeth 15 b of the internal-tooth gear 15 and the external teeth 14 b of the external-tooth gear 14. When the load F is received at the internal-tooth receiving point A, and transmitted to the external-tooth receiving point B through the wedge member 16B, the line K connecting between the internal-tooth receiving point A and the external-tooth receiving point B is located outward relative to the gear center P2 of the external-tooth gear 14 and the gear center P1 of the internal-tooth gear 15. Thus, the distance “j” is increased to a distance “J”, and the action point “q” is moved to an action point “Q”, so that the wedge member 16B receives a turning force (see the arrow H) around the external-tooth receiving point B.

Thus, a portion of the arc-shaped outer surface 16 a of the wedge member 16B ranging from the external-tooth receiving point B to the trailing edge thereof strongly bites into or contacts the arc-shaped inner peripheral surface of the large-diameter hole 14 c of the external-tooth gear 14, and a portion of the arch-shaped inner surface 16 b of the wedge member 16B ranging from the internal-tooth receiving point A to the leading edge thereof strongly bites into or contacts the arc-shaped outer peripheral surface of the small-diameter shank 15 c of the internal-tooth gear 15. In this manner, even if the load F is imposed on the second bracket 5 from the seat back 3, the wedge member 16B is urged in a biting or contact direction to reduce a shock to be given to the wedge member 16B, so as to prevent the seat back 3 from being reclined. The same operation and effect as those described above can also be obtained when a counterclockwise load F is imposed on the on the second bracket 5 from the seat back 3.

In addition, a force causing release of the biting or wedged state is reduced. This makes it possible to use a smaller spring with a lower spring force as the spring member 18, and thereby allow the spring member 18 to have outer dimensions for being adequately housed in an inner space of the large-diameter hole 14 c of the external-tooth gear 14. The wedge members 16A, 16B can also be reduced in size, such as length.

Further, each of the wedge members 16A, 16B has the arc-shaped outer surface 16 a having a diameter slightly less than that of the arc-shaped inner peripheral surface of the large-diameter hole 14 c of the external-tooth gear 14, and the arc-shaped inner surface 16 b having a diameter slightly greater than that of the arc-shaped outer peripheral surface of the small-diameter shank 15 c of the internal-tooth gear 15. Thus, the arc-shaped outer surfaces 16 a and the arc-shaped outer surfaces 16 b of the wedge members 16A, 16B are always moved circularly in the eccentric space 10 with a small clearance. This allows variations in the concentric space 10 due to vitiations in machining accuracy of an arc-shaped inner peripheral surface of the large-diameter hole 14 c of the external-tooth gear 14 and an arc-shaped outer peripheral surface of the small-diameter shank 15 c of the internal-tooth gear 15, to be absorbed by the wedge members 16A, 16B.

In the above embodiment, as to respective circumferential lengths of the arc-shaped outer surface 16 a and the arc-shaped inner surface 16 b in each of the wedge members 16A, 16B, the arc-shaped outer surface 16 a is longer, and the arc-shaped inner surface 16 b is shorter (small in area). This conventional setting of circumferential lengths involves the risk of concentration of load in the small-diameter shank 15 c of the internal-tooth gear 15 due to increase in surface pressure of the arc-shaped inner surface 16 b having a shorter length. Specifically, referring to FIG. 14, the circumferential length of the arc-shaped inner surface 16 b in each of the wedge members 16A, 16B is about ⅛ of the circumferential length of the small-diameter shank 15 c.

With a focus on this point, as shown in FIG. 15, the arc-shaped inner surface 16 b in each of the wedge members 16A, 16B is designed to increase a circumferential length in such a manner that it is to be about ⅓ of the circumferential length of the small-diameter shank 15 c. While the arc-shaped inner surface 16 b in FIG. 15 has a circumferential length greater than that of the arc-shaped outer surfaces 16 a (the circumferential length of the arc-shaped inner surface 16 b is about ¼ of the circumferential length of the small-diameter shank 15 c), it may have approximately the same circumferential length as that of the small-diameter shank 15 c.

Further, in each of the wedge members 16A, 16B, a leading-end cutout portion 16 f is formed in a portion of the arc-shaped outer surfaces 16 a on the side of the leading edge 16 c, and the wedged-state release member 19 is in contact with the leading-end cutout portion 16 f.

FIG. 15A shows a state when no load acts on the seat back 3 (second bracket 5). In this state, a line K connecting between an internal-tooth receiving point “a” where the arc-shaped inner surface 16 b of the wedge member 16B comes into contact with the arc-shaped outer peripheral surface of the small-diameter shank 15 c of the internal-tooth gear 15, and an external-tooth receiving point “b” where the arc-shaped outer surface 16 a of the wedge member 16B comes into contact with the arc-shaped inner peripheral surface of the large-diameter hole 14 c of the external-tooth gear 14, is located outward or offset relative to each of a gear center P2 of the external-tooth gear 14 and a gear center P1 of the internal-tooth gear 15. The line K is spaced apart from the gear center P1 by a distance “j”, and an intersecting point “q” between the line K and a line I extending from the gear center P1, in the distance “j”, corresponds to an action point of the internal-tooth receiving point “a” and the external-tooth receiving point “b” of the wedge member 16B. In FIG. 15A, P3 indicates a center of the arc-shaped outer surface 16 a of the wedge member 16B, and P4 indicates a center of the arc-shaped inner surface 16 b of the wedge member 16B. Although not shown herein, the wedge member 16A has the same effects as those of the wedge member 16B as well as the following effects.

As shown in FIG. 15B, when a load F is imposed on the second bracket 5 from the seat back 3 clockwise, the load F acts on the small-diameter shank 15 c of the internal-tooth gear 15, on the basis of an engagement point between the internal teeth 15 b of the internal-tooth gear 15 and the external teeth 14 b of the external-tooth gear 14. When the load F is received at the internal-tooth receiving point A, and transmitted to the external-tooth receiving point B through the wedge member 16B, the line K connecting between the internal-tooth receiving point A and the external-tooth receiving point B is located outward relative to the gear center P2 of the external-tooth gear 14 and the gear center P1 of the internal-tooth gear 15. Then, if the distance “j” is reduced to a distance “J” (distance j<J), and the action point q is moved to an action point Q, the line K connecting between the internal-tooth receiving point A and the external-tooth receiving point B in the wedge member 16B will be kept at a position located outward relative to the gear center P2 of the external-tooth gear 14 and the gear center P1 of the internal-tooth gear 15, so that the wedge member 16B receives a turning force (see the arrow H) around the external-tooth receiving point B.

Thus, a portion of the arc-shaped outer surface 16 a of the wedge member 16B ranging from the external-tooth receiving point B to the trailing edge thereof strongly bites into or contacts the arc-shaped inner peripheral surface of the large-diameter hole 14 c of the external-tooth gear 14, and a portion of the arch-shaped inner surface 16 b of the wedge member 16B ranging from the internal-tooth receiving point A to the leading edge thereof strongly bites into or contacts the arc-shaped outer peripheral surface of the small-diameter shank 15 c of the internal-tooth gear 15. In this manner, even if the load F is imposed on the second bracket 5 from the seat back 3, the wedge member 16 B is urged in a biting or contact direction to reduce a shock to be given to the wedge member 16B, and prevent the seat back 3 from being reclined. The same operation and effect as those described above can also be obtained when a counterclockwise load F is imposed on the on the second bracket 5 from the seat back 3.

In addition, a force causing release of the biting or wedged state is reduced. This makes it possible to use a smaller spring with a lower spring force as the spring member 18, and thereby allow the spring member 18 to have outer dimensions for being adequately housed in an inner space of the large-diameter hole 14 c of the external-tooth gear 14.

Further, as to the respective circumferential lengths of the arc-shaped outer surface 16 a and the arc-shaped inner surface 16 b in each of the wedge members 16A, 16B, they are approximately the same, or the arc-shaped inner surface 16 b is relatively longer (approximately the same or larger in area). Thus, a surface pressure of the arc-shaped inner surface 16 b can be reduced to reduce the risk of concentration of load in the small-diameter shank 15 c of the internal-tooth gear 15.

As shown in FIGS. 16A and 16B, when the wedged-state release member 19 is rotated clockwise (see the arrow), for example, as shown in FIG. 16B, according to rotation of the control shaft 20 in conjunction with a manual operation of the handle 7, one edge 19 f of the wedged-state release member 19 is brought into contact with the cutout portion 16 f of the wedge member 16A, to move the wedge member 16A clockwise so as to loosen the wedged state of the wedge member 16A. In conjunction with the clockwise movement of the wedge member 16A, the wedge member 16B is also moved clockwise through the spring member 18. Thus, an angle of the second bracket 5 relative to the first bracket 4, i.e. a frontward/rearward reclining angle of the seat back 3, can be adjusted in the same manner as that in the aforementioned embodiment. In the above operation, the wedged-state release portion 19 e of the wedged-state release member 19 is brought into contact with the cutout portion 16 f formed in the arc-shaped outer surface 16 a of the wedge member 16A. That is, the wedged-state release portion 19 e presses a portion of the wedge member 16B located close to the outer surface thereof, against the aforementioned turning force (see the arrow H), to allow the wedge member to be moved in a direction opposite to that of the turning force. Thus, the wedged state of the wedge member can be more easily relaxed or released.

In the wedge members 16A and 16B illustrated in FIGS. 15 and 16, if it is necessary to reduce an operation force for rotating the control shaft using the handle 7, it is conceivable to reduce a spring or biasing force of the spring member 18.

In this case, during a process of rotating the control shaft 20 using the handle 7 which is initiated from the state illustrated in FIG. 17A, when the wedged-state release member is rotated, for example, clockwise (see the arrow) as shown in FIG. 17B, one of opposite edges 19 f of the wedge-state release portion (first wedge-state release portion) 19 e is brought into contact with the leading-end cutout portion 16 f of the wedge member 16A, and pushed clockwise to relax or release the wedged state of the wedge member 16A.

During this process, when the spring member 18 has a sufficiently strong spring or biasing force, the wedge member 16B can also be pushed clockwise through the spring member 18 in conjunction with movement of the wedge member 16A.

If the biasing force of the spring member 18 is reduced, the wedge member 16B is not pushed clockwise through the spring member 18, but an inward portion of the trailing edge 16 d of the wedge member 16A adjacent to the inner peripheral surface thereof will be brought into contact with an inward portion of the trailing edge 16 d of the wedge member 16B adjacent to the inner peripheral surface thereof to push the wedge member 16B clockwise, as shown in FIG. 17C.

That is, the inward portion of the trailing edge 16 d of the wedge member 16A directly pushes the inward portion of the trailing edge 16 d of the wedge member 16B. Thus, the wedge members 16A, 16B are likely to be frictioned against one another to cause difficulty in smoothly moving the wedge members 16A, 16B circularly in a release direction, resulting in poor operational feeling.

With a focus on this point, as shown in FIG. 18A, an arc-shaped portion (second wedged-state release portion) 19 h of the wedged-state release member 19 located between the respective trailing edges 16 d, 16 d of the wedge members 16A, 16B is extended in an arc direction by a length S2 (length S2> a length S1 of the arc-shaped portion 19 h in FIG. 17), in such a manner that one edge 19 f of the wedged-state release portion (first wedged-state release portion) 19 e is brought into contact with the leading-end cutout portion 16 f of the wedge member 16A adjacent to the outer peripheral surface thereof to push the wedge member 16A clockwise so as to relax or release the wedged state, as shown in FIG. 18B, and then, before the inward portion of the trailing edge 16 d of the wedge member 16A is brought into contact with the inward portion of the trailing edge 16 d of the wedge member 16B, the arc-shaped portion (second wedged-state release portion) 19 h is brought into contact with an outward portion of the trailing edge 16 d of the wedge member 16B adjacent to the outer peripheral surface thereof to push the wedge member 16B, as shown in FIG. 18C.

Thus, in the wedge members 16A, 16B illustrated in FIG. 18, the operational force for rotating the control shaft 20 using the handle 7 can be reduced by lowering a spring or biasing force of the spring member 18. Additionally, the outward portion of the trailing edge 16 d of the wedge member 16B is pushed by the arc-shaped portion (second wedged-state release portion) 19 h of the wedged-state release member 19 to prevent friction between the wedge members 16A, 16B. This allows the wedge members 16A, 16B to be smoothly moved circularly in the release direction so as to provide enhanced operational feeling.

The structures of the wedge member 16A, 16B and the wedged-state release member 19 in the above embodiment illustrated in FIG. 18 can provide a low resistance because one edge 19 f of the wedged-state release portion (first wedged-state release portion) 19 e pushes the wedge member 16A in a direction allowing a volume of the eccentric space 10 for receiving the wedge member 16A to be increased. In contrast, when the arc-shaped portion (second wedged-state release portion) pushes the wedge member 16B, the wedge member 16B is pushed in a direction causing a smaller volume of the eccentric space 10 for receiving the wedge member 16A. This is likely to lead to a higher resistance due to increases in friction between the arc-shaped outer peripheral surface 16 a of the wedge member 16B and the arc-shaped inner peripheral surface of the lager-diameter hole 14 c, and a component force of the pushing force.

In order to avoid this risk, as shown in FIG. 19A and FIG. 20, each of the wedge members 16A, 16B is formed with a notch 16 g at a position adjacent to the outer peripheral surface thereof and on the side of the leading edge thereof. Further, the wedged-state release member 19 is formed with a first wedged-state release portion 19 i and a second wedged-state release portion 19 j each adapted to be fitted into a corresponding one of the notches 16 g. Thus, as shown in FIG. 19B, the first wedged-state release portion 19 i is brought into contact with a trailing face 16 h of the notch 16 g of the wedge member 16A to push the wedge member 16A in a release direction so as to relax the wedged state. Then, as shown in FIG. 19C, before the trailing edge 16 d of the wedge member 16A is brought into contact with the railing edge 16 d of the wedge member 16B, the second wedged-state release portion 19 j is brought into contact with a leading face 16 i of the notch 16 g of the wedge member 16B to drag the wedge member 16B.

Thus, in the wedge members 16A, 16B illustrated in FIG. 18, the operational force for rotating the control shaft 20 using the handle 7 can be reduced by lowering a spring or biasing force of the spring member 18. Additionally, the second wedged-state release portion 19 j drags the leading face 16 i of the notch 16 g of the wedge member 16B. This makes it possible to reduce a friction between the arc-shaped outer peripheral surface 16 a of the wedge member 16B and the arc-shaped inner peripheral surface of the lager-diameter hole 14 c, and a component force of the pushing force so as to provide a reduced resistance. This allows the wedge members 16A, 16B to be smoothly moved circularly in the release direction so as to provide enhanced operational feeling.

While the ring-shaped retainer member 22 in the above embodiment illustrated in FIG. 1 to 18 is crimped to the internal-tooth gear 14 while holding the eternal-tooth gear 14 by the ring-shaped retainer member 22, an appropriate position of an outer peripheral portion of the ring-shaped retainer member 22 may be fixed to an outer peripheral portion of the internal-tooth gear 14 by laser welding while holding the internal-tooth gear 15 by the ring-shaped retainer member 22, as shown in FIG. 20.

In the above embodiment, the wedged-state release member 19 is held by the external-tooth gear 14 in such a manner that-the outer peripheral surface of the wedged-state release member 19 is rotatably fitted in the large-diameter hole 14 c formed in the central region of the external-tooth gear 14. This allows the wedged-state release member 19 to be stably rotated along the large-diameter hole 14 c of the external-tooth gear 14 and to be increased in size so as to have enhanced strength. In addition, this makes it possible to simplify the shape of the wedged-state release member 19 so as to facilitate reduction in production cost.

In the above embodiment, in the state after the wedged-state release member 19 is fitted in the large-diameter hole 14 c, the clearance grooves 19 a can prevent needless interference between the wedged-state release member 19 and the wedge members 16A, 16B.

In the above embodiment, the control shaft 20 for selectively rotating the wedged-state release member 19 is fixed to the wedged-state release member 19 by inserting the noncircular portion (fixing portion) 20 a of the control shaft 20 into the noncircular hole 19 d of the wedged-state release member 19. Thus, the control shaft 20 is simply inserted into the hole 15 e of the small-diameter shank 15 c of the internal-tooth gear 15 in a non-fitting manner, so that the need for fitting the cylindrical-shaped portion of the wedged-state release member 19 into the small-diameter shank 15 c of the internal-tooth gear 15 can be eliminated. This makes it possible to increase the wall thickness of the small-diameter shank 15 c and the diameter of the control shaft 20 so as to provide enhanced strength thereof. Further, the control shaft 20 can be fixedly connected to the wedged-state release member 19 simply by inserting the noncircular portion 20 a of the control shaft 20 into the noncircular hole 19 d of the wedged-state release member 19, without the need for a spline connection between the cylindrical-shaped portion of the wedged-state release member 19 and the control shaft 20. Thus, the insertion/connection structure can be simplified.

While the bracket angle adjustment mechanism according to the above embodiment has been designed to adjust a relative angle between the brackets 4, 5 related to a reclining function of the vehicle seat assembly 1, it is understood that the present invention may be applied to any other type of bracket angle adjustment mechanism for adjusting a relative angle between one bracket 4 and the other bracket 5 for use, for example, in a lifter for a vehicle seat 1 or a vehicle power window apparatus.

As described above, an inventive bracket angle adjustment mechanism comprises a first bracket including an external-tooth gear, a second bracket including an internal-tooth gear which has a larger number of internal teeth than that of external teeth of the external-tooth gear, a pair of wedge members fitted in an eccentric space which is defined between a large-diameter hole formed in a central region of the external-tooth gear and a small-diameter shank constituting a central portion of the internal-tooth gear, in a state when the external-tooth gear and the internal-tooth gear are partly engaged with one another, a spring member applying a biasing force to each of the pair of wedge members in a wedging direction, and a wedged-state release member disposed between respective wedging-directional leading edges of the pair of wedge members, the wedged-state release member being operable, when rotated by a control shaft associated therewith, to move the pair of wedge members together with the spring member in a wedged-state release direction circularly in the eccentric space, whereby the small-diameter shank is eccentrically moved relative to the large-diameter hole to allow an engagement position of the internal-tooth gear relative to the external-tooth gear to be changed so as to adjust an angle of the second bracket relative to the first bracket. The wedged-state release member is held by the external-tooth gear in such a manner that an outer peripheral surface of the wedged-state release member is rotatably fitted into the large-diameter hole formed in the central region of the external-tooth gear.

In the bracket angle adjustment mechanism, the wedged-state release member may be formed with a clearance groove for allowing the wedged-state release member to avoid interference with the wedge members.

The bracket angle adjustment mechanism may further include a control shaft for selectively rotating the wedge-state release member. The control shaft may have an attaching portion which is inserted into and fastened to the wedge-state release member in a non-rotatable manner.

In the bracket angle adjustment mechanism, the wedge-state release member may be formed with a pressing portion for preventing the wedge members from rising up theretoward.

In the bracket angle adjustment mechanism, the spring member may have an outer shape allowing for being housed in the wedge-state release member.

In the bracket angle adjustment mechanism, the wedge-state release member may include a first wedge-state release portion disposed between respective leading edges of the pair of wedge members, and a second wedge-state release portion disposed between respective trailing edges of the pair of wedge members. In this case, the first wedge-state release portion may be designed to be brought into contact with the leading edge of a first one of the wedge members so as to push and move the first wedge member, ahead of the second wedge-state release portion, and the second wedge-state release portion may be designed to be brought into contact with the trailing edge of a second one of the wedge members so as to push and move the second wedge member, before the trailing edge of the first wedge member moved by the first wedge-state release portion is brought into contact with the trailing edge of the second wedge member.

In the bracket angle adjustment mechanism, the pair of wedge members may include, respectively, first and second notches each formed on the side of a leading edge of a corresponding one thereof, and the wedge-state release member may include first and second wedge-state release portions adapted to be fitted, respectively, into the first and second notches. In this case, the first wedge-state release portion may be designed to be brought into contact with a trailing face of the first notch of a first one of the wedge members so as to push and move the first wedge member, ahead of the second wedge-state release portion, and the second wedge-state release portion may be designed to be brought into contact with a leading face of the second notch of a second one of the wedge members so as to drag the second wedge member, before a trailing edge of the first wedge member moved by the first wedge-state release portion is brought into contact with a trailing edge of the second wedge member.

The bracket angle adjustment mechanism may be used with a seat assembly having a seat back and a seat cushion to adjust a frontward/rearward angle of the seat back relative to the seat cushion, wherein one of the first and second brackets is fixed to the seat back, and the other bracket is fixed to the seat cushion.

With these constructions, the wedged-state release member is held by the external-tooth gear in such a manner that an outer peripheral surface of the wedged-state release member is rotatably fitted into the large-diameter hole formed in the central region of the external-tooth gear. This makes it possible to increase in size and strength of the wedged-state release member, and simplify a shape of the wedged-state release member so as to reduce in production cost.

This application is based on patent application Nos. 2004-379692 and 2005-277533 filed in Japan, the contents of which are hereby incorporated by references.

As this invention may be embodied in several forms without departing from the spirit of essential characteristics thereof, the present embodiment is therefore illustrative and not restrictive, since the scope of the invention is defined by the appended claims rather than by the description preceding them, and all changes that fall within metes and bounds of the claims, or equivalence of such metes and bounds are therefore intended to embraced by the claims. 

1. A bracket angle adjustment mechanism comprising: a first bracket including an external-tooth gear; a second bracket including an internal-tooth gear which has a larger number of internal teeth than that of external teeth of the external-tooth gear; a pair of wedge members fitted in an eccentric space which is defined between a large-diameter hole formed in a central region of the external-tooth gear and a small-diameter shank constituting a central portion of the internal-tooth gear, in a state when the external-tooth gear and the internal-tooth gear are partly engaged with one another; a spring member applying a biasing force to each of the pair of wedge members in a wedging direction; a control shaft; and a wedge-state release member disposed between respective wedging-directional leading edges of the pair of wedge members, the wedge-state release member including a circular bottom, an arc-shaped first wedge-state release portion at a position of circumference of the circular bottom and an arc-shaped second wedge-state release portion at a position opposed the first wedge-state release portion, the wedge-state release member being concentrically fastened to the control shaft, the wedge-state release member being operable, when rotated by the control shaft associated therewith, to move the pair of wedge members together with the spring member in a wedge-state release direction circularly in the eccentric space, whereby the small-diameter shank is eccentrically moved relative to the large-diameter hole to allow an engagement position of the internal-tooth gear relative to the external-tooth gear to be changed so as to adjust an angle of the second bracket relative to the first bracket, wherein the wedge-state release member is held by the external-tooth gear in such a manner that an outer peripheral surface of the wedge-state release member is rotatably fitted in an inner peripheral surface of the large-diameter hole formed in the central region of the external-tooth gear by the first and second wedge-state release portions.
 2. The bracket angle adjustment mechanism as defined in claim 1, wherein the wedge-state release member is formed with a pressing portion for preventing the wedge members from rising up theretoward.
 3. The bracket angle adjustment mechanism as defined in claim 1, wherein the spring member has an outer shape allowing for being housed in the wedge-state release member.
 4. The bracket angle adjustment mechanism as defined in claim 1, wherein the first wedge-state release portion is disposed between respective leading edges of the pair of wedge members; and the second wedge-state release portion is disposed between respective trailing edges of the pair of wedge members, wherein: the first wedge-state release portion is designed to be brought into contact with the leading edge of a first one of the wedge members so as to push and move the first wedge member, before the second wedge-state release portion is brought into contact with the trailing edge of a second one of the wedge members; and the second wedge-state release portion is designed to be brought into contact with the trailing edge of the second one of the wedge members so as to push and move the second wedge member, before the trailing edge of the first wedge member moved by the first wedge-state release portion is brought into contact with the trailing edge of the second wedge member.
 5. The bracket angle adjustment mechanism as defined in claim 1, wherein: the pair of wedge members include, respectively, first and second notches each formed on the side of a leading edge of a corresponding one thereof; and the first and second wedge-state release portions are adapted to be fitted, respectively, into the first and second notches, wherein: the first wedge-state release portion is designed to be brought into contact with a trailing face of the first notch of a first one of the wedge members so as to push and move the first wedge member, before the second wedge-state release portion is brought into contact with a leading face of the second notch of a second one of the wedge members; and the second wedge-state release portion is designed to be brought into contact with the leading face of the second notch of the second one of the wedge members so as to drag the second wedge member, before a trailing edge of the first wedge member moved by the first wedge-state release portion is brought into contact with a trailing edge of the second wedge member.
 6. The bracket angle adjustment mechanism as defined in claim 1, which is used with a seat assembly having a seat back and a seat cushion to adjust a frontward/rearward angle of the seat back relative to the seat cushion, wherein one of the first and second brackets is fixed to the seat back, and the other bracket is fixed to the seat cushion.
 7. The bracket angle adjustment mechanism as defined in claim 1, wherein the wedge-state release member is formed with a clearance groove for allowing the wedge-state release member to avoid interference with the wedge members.
 8. The bracket angle adjustment mechanism as defined in claim 7, wherein the wedge-state release member is formed with a pressing portion for preventing the wedge members from rising up theretoward.
 9. The bracket angle adjustment mechanism as defined in claim 7, wherein the spring member has an outer shape allowing for being housed in the wedge-state release member.
 10. The bracket angle adjustment mechanism as defined in claim 7, wherein the first wedge-state release portion is disposed between respective leading edges of the pair of wedge members; and the second wedge-state release portion is disposed between respective trailing edges of the pair of wedge members, wherein: the first wedge-state release portion is designed to be brought into contact with the leading edge of a first one of the wedge members so as to push and move the first wedge member, before the second wedge-state release portion is brought into contact with the trailing edge of a second one of the wedge members; and the second wedge-state release portion is designed to be brought into contact with the trailing edge of the second one of the wedge members so as to push and move the second wedge member, before the trailing edge of the first wedge member moved by the first wedge-state release portion is brought into contact with the trailing edge of the second wedge member.
 11. The bracket angle adjustment mechanism as defined in claim 7, wherein: the pair of wedge members include, respectively, first and second notches each formed on the side of a leading edge of a corresponding one thereof; and the first and second wedge-state release portions are adapted to be fitted, respectively, into the first and second notches, wherein: the first wedge-state release portion is designed to be brought into contact with a trailing face of the first notch of a first one of the wedge members so as to push and move the first wedge member, before the second wedge-state release portion is brought into contact with a leading face of the second notch of a second one of the wedge members; and the second wedge-state release portion is designed to be brought into contact with the leading face of the second notch of a second one of the wedge members so as to drag the second wedge member, before a trailing edge of the first wedge member moved by the first wedge-state release portion is brought into contact with a trailing edge of the second wedge member.
 12. The bracket angle adjustment mechanism as defined in claim 7, which is used with a seat assembly having a seat back and a seat cushion to adjust a frontward/rearward angle of the seat back relative to the seat cushion, wherein one of the first and second brackets is fixed to the seat back, and the other bracket is fixed to the seat cushion.
 13. The bracket angle adjustment mechanism as defined in claim 1, wherein the control shaft has an attaching portion which is inserted into and fastened to the circular bottom of the wedge-state release member in a non-rotatable manner.
 14. The bracket angle adjustment mechanism as defined in claim 13, wherein the wedge-state release member is formed with a pressing portion for preventing the wedge members from rising up theretoward.
 15. The bracket angle adjustment mechanism as defined in claim 13, wherein the spring member has an outer shape allowing for being housed in the wedge-state release member.
 16. The bracket angle adjustment mechanism as defined in claim 13, wherein the first wedge-state release portion is disposed between respective leading edges of the pair of wedge members; and the second wedge-state release portion is disposed between respective trailing edges of the pair of wedge members, wherein: the first wedge-state release portion is designed to be brought into contact with the leading edge of a first one of the wedge members so as to push and move the first wedge member, before the second wedge-state release portion is brought into contact with the trailing edge of a second one of the wedge members; and the second wedge-state release portion is designed to be brought into contact with the trailing edge of the second one of the wedge members so as to push and move the second wedge member, before the trailing edge of the first wedge member moved by the first wedge-state release portion is brought into contact with the trailing edge of the second wedge member.
 17. The bracket angle adjustment mechanism as defined in claim 13, wherein: the pair of wedge members include, respectively, first and second notches each formed on the side of a leading edge of a corresponding one thereof; and the first and second wedge-state release portions are adapted to be fitted, respectively, into the first and second notches, wherein: the first wedge-state release portion is designed to be brought into contact with a trailing face of the first notch of a first one of the wedge members so as to push and move the first wedge member, before the second wedge-state release portion is brought into contact with a leading face of the second notch of a second one of the wedge members; and the second wedge-state release portion is designed to be brought into contact with the leading face of the second notch of the second one of the wedge members so as to drag the second wedge member, before a trailing edge of the first wedge member moved by the first wedge-state release portion is brought into contact with a trailing edge of the second wedge member.
 18. The bracket angle adjustment mechanism as defined in claim 13, which is used with a seat assembly having a seat back and a seat cushion to adjust a frontward/rearward angle of the seat back relative to the seat cushion, wherein one of the first and second brackets is fixed to the seat back, and the other bracket is fixed to the seat cushion. 